Publications

Found 31 results
Author [ Title(Desc)] Year
Filters: First Letter Of Last Name is B  [Clear All Filters]
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z 
C
Antler G, Turchyn AV, Ono S, Sivan O, Bosak T.  2017.  Combined 34 S, 33 S and 18 O isotope fractionations record different intracellular steps of microbial sulfate reduction. Geochimica et Cosmochimica Acta. 203:364–380.
Meredith LK, Rao D, Bosak T, Klepac-Ceraj V, Tada KR, Hansel CM, Ono S, Prinn RG.  2014.  Consumption of atmospheric hydrogen during the life cycle of soil-dwelling actinobacteria. Environmental Microbiology Reports. 6:226–238.
D
Joelsson LMT, Schmidt JAlbrecht, Nilsson EJK, Blunier T, Griffith DWT, Ono S, Johnson MStanley.  2015.  Development of a new methane tracer: kinetic isotope effect of 13CH3D+ OH from 278 to 313K.. Atmospheric Chemistry & Physics Discussions. 15
E
Ono S, Beukes NJ, Rumble D, Fogel ML.  2006.  Early evolution of atmospheric oxygen from multiple-sulfur and carbon isotope records of the 2.9 Ga Mozaan Group of the Pongola Supergroup, Southern Africa. South African Journal of GeologySouth African Journal of Geology. 109(1-2):97-108.
Sim M.S., Ono S, Donovan K, Templer S.P., Bosak T..  2011.  Effect of electron donors on the fractionation of sulfur isotopes by a marine Desulfovibrio sp.. Geochimica et Cosmochimica ActaGeochimica et Cosmochimica Acta. 75(15):4244-4259.
Sim M.S., Ono S., Bosak T..  2012.  Effects of Iron and Nitrogen Limitation on Sulfur Isotope Fractionation during Microbial Sulfate Reduction. Applied and Environmental Microbiology.
Sim M.S., Ono S, Bosak T.  2012.  Effects of Iron and Nitrogen Limitation on Sulfur Isotope Fractionation during Microbial Sulfate Reduction.. Applied and environmental microbiologyApplied and environmental microbiology. :AEM.01842-12-.
Inagaki F., Hinrichs K.-U., Kubo Y., Bowles M.W, Heuer V.B, Hong W.-L., Hoshino T., Ijiri A., Imachi H., Ito M. et al..  2015.  Exploring deep microbial life in coal-bearing sediment down to  2.5 km below the ocean floor. Science. 349:420-424.
Inagaki F., Hinrichs K.-U., Kubo Y., Bowles M.W, Heuer V.B, Hong W.-L., Hoshino T., Ijiri A., Imachi H., Ito M. et al..  2015.  Exploring deep microbial life in coal-bearing sediment down to  2.5 km below the ocean floor. Science. 349:420-424.
Inagaki F., Hinrichs K.-U., Kubo Y., Bowles M.W, Heuer V.B, Hong W.-L., Hoshino T., Ijiri A., Imachi H., Ito M. et al..  2015.  Exploring deep microbial life in coal-bearing sediment down to  2.5 km below the ocean floor. Science. 349:420-424.
F
Barry P.H, de Moor J.M, Giovannelli D., Schrenk M., Hummer D.R, Lopez T., Pratt C.A, Y. Segura A, Battaglia A., Beaudry P. et al..  2019.  Forearc carbon sink reduces long-term volatile recycling into the mantle. Nature. 568:487–492.
Barry P.H, de Moor J.M, Giovannelli D., Schrenk M., Hummer D.R, Lopez T., Pratt C.A, Y. Segura A, Battaglia A., Beaudry P. et al..  2019.  Forearc carbon sink reduces long-term volatile recycling into the mantle. Nature. 568:487–492.
Barry P.H, de Moor J.M, Giovannelli D., Schrenk M., Hummer D.R, Lopez T., Pratt C.A, Y. Segura A, Battaglia A., Beaudry P. et al..  2019.  Forearc carbon sink reduces long-term volatile recycling into the mantle. Nature. 568:487–492.
Barry P.H, de Moor J.M, Giovannelli D., Schrenk M., Hummer D.R, Lopez T., Pratt C.A, Y. Segura A, Battaglia A., Beaudry P. et al..  2019.  Forearc carbon sink reduces long-term volatile recycling into the mantle. Nature. 568:487–492.
Barry P.H, de Moor J.M, Giovannelli D., Schrenk M., Hummer D.R, Lopez T., Pratt C.A, Y. Segura A, Battaglia A., Beaudry P. et al..  2019.  Forearc carbon sink reduces long-term volatile recycling into the mantle. Nature. 568:487–492.
T. B, M. BJW, R. FM, B. L, P. PA, S. O, S. SM.  2010.  Formation and stability of oxygen-rich bubbles that shape photosynthetic mats. GeobiologyGeobiology. 8:45-55.
Sim MSub, Wang DT, Zane GM, Wall JD, Bosak T, Ono S.  2013.  Fractionation of sulfur isotopes by Desulfovibrio vulgaris mutants lacking hydrogenases or type I tetraheme cytochrome c3. Frontiers in MicrobiologyFrontiers in Microbiology. 4(June):1-10.
I
Zaarur S, Wang DT, Bosak T, Ono S.  2017.  Influence of phosphorus and cell geometry on the fractionation of sulfur isotopes by several species of Desulfovibrio during microbial sulfate reduction. Frontiers in Microbiology. 8:890.
Stefánsson A, Hilton DR, Sveinbjörnsdóttir ÁE, Torssander P, Heinemeier J, Barnes JD, Ono S, Halldórsson SAri, Fiebig J, Arnórsson S.  2017.  Isotope systematics of Icelandic thermal fluids. Journal of Volcanology and Geothermal Research. :-.
L
Sim M.S., Bosak T, Ono S.  2011.  Large sulfur isotope fractionation does not require disproportionation. ScienceScience. 333(6038):74-77.
M
Guy BM, Ono S, Gutzmer J., Kaufman AJ, Lin Y., Fogel M.L., Beukes N.J..  2012.  A multiple sulfur and organic carbon isotope record from non-conglomeratic sedimentary rocks of the Mesoarchean Witwatersrand Supergroup, South Africa. Precambrian ResearchPrecambrian Research. 216-219:208-231.
Leavitt WD, Cummins R, Schmidt ML, Sim M-S, Ono S, Bradley AS, Johnston DT.  2014.  Multiple sulfur isotope signatures of sulfite and thiosulfate reduction by the model dissimilatory sulfate-reducer, Desulfovibrio alaskensis str. G20. Frontiers in Microbiology. 5
N
Luo G, Junium CK, Izon G, Ono S, Beukes NJ, Algeo TJ, Cui Y, Xie S, Summons RE.  2018.  Nitrogen fixation sustained productivity in the wake of the Palaeoproterozoic Great Oxygenation Event. Nature Communications. 9:978.
O
Pajusalu M, Borlina CS, Seager S, Ono S, Bosak T.  2018.  Open-source sensor for measuring oxygen partial pressures below 100 microbars. PloS one. 13:e0206678.
Pajusalu M, Borlina CS, Seager S, Ono S, Bosak T.  2018.  Open-source sensor for measuring oxygen partial pressures below 100 microbars. PloS one. 13:e0206678.

Pages